SYNTHESIS, CHIROPTICAL AND ELECTROCHEMICAL STUDIES OF DIOXOURANIUM(VI) COMPLEXES OF ALDIMINE DERIVATIVES OF L- D-HISTIDINE AND CRYSTAL-STRUCTURE OF E-L-HISTIDINATO)URANIUM(VI)-WATER-METHANOL(1/1/1)/
S. Panchanan et al., SYNTHESIS, CHIROPTICAL AND ELECTROCHEMICAL STUDIES OF DIOXOURANIUM(VI) COMPLEXES OF ALDIMINE DERIVATIVES OF L- D-HISTIDINE AND CRYSTAL-STRUCTURE OF E-L-HISTIDINATO)URANIUM(VI)-WATER-METHANOL(1/1/1)/, Journal of the Chemical Society. Dalton transactions, (16), 1994, pp. 2381-2390
A series of new dioxouranium(VI) complexes has been synthesised using
N-(salicylidene)-L-histidine (H2sal-L-his) and N-(o-vanillylidene)-L-h
istidine (H2van-L-his) and the corresponding D-histidines.They have be
en characterized by elemental analyses and physicochemical studies. Th
e crystal and molecular structures of [UO2(van-L-his)(bipy)].MeOH.H2O
(bipy = 2,2'-bipyridine) have been determined by X-ray crystallography
. The aldimine ligand in this compound is tridentate. The methanol and
water molecules are hydrogen bonded to each other and the water molec
ule to the carboxylate 0 atom. The diamagnetic UO22+ entity serves as
a chiroptical probe, undergoing stereospecific complex formation with
the aldimine ligands, as well as for the interpretation of their H-1 N
MR spectra, which in conjunction with two-dimensional NMR spectra, rev
eal the different spin-spin interactions, including the long range one
between the azomethine (CH=N) and H(alpha) proton of the amino acid r
esidue. The CD and NMR spectral data of the quasi-enantiomorphous UO22
+ complexes containing the L-/D-amino acid residues have helped to asc
ertain the conformational differences between each such pair; these di
fferences can modulate energies of the half-filled highest occupied mo
lecular orbitals in different ways. As these orbitals are involved in
the electron-transfer process, the relevant complexes respond differen
tly when subjected to cyclic voltammetry.